Artilux Announces Groundbreaking GeSi SPAD Research Published In Nature Journal

Achieving a new milestone in CMOS photonics

Hsinchu /PRNewswire/ - Artilux, the renowned leader of GeSi (germanium-silicon) photonics technology for CMOS (complementary metal-oxide-semiconductor) based SWIR (short-wavelength infrared) sensing and imaging, announced today that the research team at Artilux has made a breakthrough in advancing SWIR GeSi SPAD (single-photon avalanche diode) technology, which has been recognized and published by Nature, one of the world's most prestigious scientific journals. The paper, titled "Room temperature operation of germanium-silicon single-photon avalanche diode," presented the Geiger-mode operation of a high-performing GeSi avalanche photodiode at room temperature, which in the past was limited to operation at a low temperature below at least 200 Kelvin. Nature's rigorous peer-review process ensures that only research of the highest caliber and broadest interest is published, and the acceptance and publication of the paper in Nature is another pivotal mark in exemplifying Artilux's leadership in CMOS-based SWIR sensing and imaging.

The research work, led by Dr. Neil Na, CTO of Artilux, has unveiled a CMOS-compatible GeSi SPAD operated at room temperature and elevated temperatures, featuring a noise-equivalent power improvement over previously demonstrated Ge-based SPADs by several orders of magnitude. The paper showcases key parameters of the GeSi SPAD, including dark count rate, single-photon detection probability at SWIR spectrum, timing jitter, after-pulsing characteristic time, and after-pulsing probability, at a low breakdown voltage and a small excess bias. As a proof of concept, three-dimensional point-cloud images were captured with TOF (direct time-of-flight) technique using the GeSi SPAD. "When we started the project, there were overwhelming evidence in the literature indicating that a room-temperature operation of GeSi SPAD is simply not possible," said Dr. Na, "and I am proud of our team turning the scientific research into a commercial reality against all odds."

The findings set a new milestone in CMOS photonics. The potential deployment of single-photon sensitive SWIR sensors, imagers, and photonic integrated circuits shall unlock critical applications in TOF sensors and imagers, LiDAR (light detection and ranging), bio-photonics, quantum computing and communication, artificial intelligence, robotics, and more. Artilux is committed to continuing its leadership in CMOS photonics technology, aiming to further contribute to the scientific community and photonics industry.

• For more information about the paper, please visit Nature's website at https://www.nature.com/articles/s41586-024-07076-x
• For more information about the related researches at Artilux, please download the whitepapers at https://www.artiluxtech.com/support/downloads